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Regeneration Behaviour of Platinum Group Metals Promoted Cracking Catalysts
D.L. Trimm et al. (Editors), Catalysts in Petroleum Refining 1989 1990 Elsevier Science Publishers B.V., Amsterdam - Printed in The Netherlands
565
REGENERATION BEHAVIOUR OF PLATINUM GROUP METALS PROMOTED CRACKING CATALYSTS P. STEINGASZNER, A.
szucs & L. MERI
Department of Chemical Technology, Technical University of Budapest, H-1521 Budapest, Budafoki 6 t 8. (Hungary)
ABSTRACT Regeneration behaviour of platinum group metals promoted cracking c a t a l y s t s has been i n v es t i g at ed by means of carbon monoxide oxidation a c t i v i t y tests and high s e n s i t i v i t y thermoanalytical methods. E f f e c t s of physical and chemical f a c t o r s - such as thermal and hydrothermal tre a tm e nt, t r a n s i t i o n metals c o n t e n t , presence of sulphur compounds as hydrogen sulphide and sulphur dioxide - on t h e carbon monoxide oxidation a c t i v i t y of s e v e r a l c o m r c i a l cracking c a t a l y s t s have been determined. Computer aided d i f f e r e n t i a l thermogravimetry has been used t o d es cr i be t h e dynamics of coke oxidation on promoted cracking c a t a l y s t s and t o determine k i n e t i c c o r r e l a t i o n s i n func tion of promoter concentration.
INTRODUCTION Catalytic
cracking
petroleum r e f i n i n g oils
into
feed
is
particles, catalyst
is
one
industry
of
for
the
most
important
processes
i n the
t h e conversion of heavy f r a c t i o n s of crude
valuable l i g h t e r products. During t h e cracking cycle a part of t h e converted
to
rendering can
he
coke which
deposits
on the surfa c e of t h e c a t a l y s t
them less a c t i v e f o r cracking. Cracking a c t i v i t y of t h e
r es t o r ed
by removal of t h e coke by burning with c ontrolle d
of air. The cracking a c t i v i t y of t h e regenerated c a t a l y s t strongly on t h e coke remaining a f t e r r eg ene ra tion, t h e r e f o r e , e s p e c i a l l y with r e g u l a r channel s t r u c t u r e z e o l i t i c cracking c a t a l y s t a coke l e v e l of less than 0.1% is m d a t o r y i n order t o g e t best r e s u l t s . Proper coke removal can be e f f e c t e d by c ar r y i n g out t h e regeneration at high temperature ( r e f . l > , i n two s t e p s ( r e f . 2) and/or by using coke oxidation improvers e i t h e r incorporated i n t o t h e cracking c a t a l y s t , or using them i n a concentrated form, added t o the c a t a l y s t ( r e f s . 1 , 7-61. Members of t h e platinum group of t h e Pe riodic Table of Elements a r e e x c e l l e n t oxidation c a t a l y s t s , and, according t o t h e pa te nt l i t e r a t u r e , t h e i r presence - alone or i n combination - on t h e cracking c a t a l y s t s i n ppm amounts results i n near complete combustion of t h e coke, preventing damaging addition
depends
566
afterburns
in
regenerator
vessel,
giving
lower coke on t h e regenerated c a t a l y s t and
coke
cracking from
make,
however
monoxide
ability
b e t t e r h e a t economy and - due t o
higher g a s o l i n e y i e l d s with lower gas
composition d a t a on c o m e r c i a l l y a v a i l a b l e promoted
are not a v a i l a b l e . The advantages mentioned r e s u l t m i n l y
catalysts
the
-
of
group metals t o c a t a l y z e oxidation of carbon
platinum
formed during r e g e n e r a t i o n t o carbon dioxide i n t h e dense
primarily
c a t a l y s t phase. I n d u s t r i a l experience has shown t h e coke combustion a c t i v i t y of oxidation improvers
to
oxidation
promoters
hydrotermal
decline
during used
repeated
with
them
use. are
As
cracking c a t a l y s t s and t h e
s u b j e c t e d t o repeated thermal and
c y c l e s , oxidative and reducing atmospheres i n t h e r e g e n e r a t o r and
r e a c t o r r e s p e c t i v e l y , and a d d i t i o n a l l y metals from t h e feed - n i c k e l , vanadium and i r o n - accumulate on them, f u r t h e r , d i f f e r e n t sulphur compounds, mainly as and hydrogen sulphide i n t h e cracking r e a c t o r and as sulphur oxides i n
thiols the
regenerator
investigations
influence
combustion a c t i v i t y ( r e f s . 1, 7, 8 ) ,
coke
were s t a r t e d t o show t h e q u a n t i t a t i v e e f f e c t s of t h e s e f a c t o r s
on carbon monoxide sensitivity
their
oxidation
activity.
Additionally,
computer aided high
methods have been used t o shed l i g h t on k i n e t i c
thermoanalytical
a s p e c t s of t h e regeneration process. EXPERIMENTAL The
regeneration
effectiveness
carbon monoxide/carbon experiments carbon been in
dioxide
1.) o r
(ref.
monoxide
specified
behaviour
of
promoted
cracking
catalyts
and
the
of oxidation improvers may be s t u d i e d e i t h e r by determining t h e by
ratio
i n f l u e gases from batch r e g e n e r a t i o n
measuring t h e carbon monoxide conversion i n a
and
oxygen
c o n t a i n i n g gas
led
over
the
c a t a l y s t under
conditions
(refs.
5,9). I n t h e p r e s e n t work t h e latter method has
used by feeding a gas stream containing 2 % by volume of carbon monoxide
air i n t o an e l e c t r i c a l l y heated isothermal q u a r t z r e a c t o r containing t h e
c a t a l y s t , at a flow rate of 30 l i t e r s / h o u r . The carbon monoxide content of t h e feed
gas,
infrared
as t h a t
as well analyzers.
The
of
volume
t h e e f f l u e n t has been measured by means of of
the
catalysts
was
6.2
ml
in
all
experiments. Catalyst
AF,
BF,
and
CF, all c o m e r c i a l l y a v a i l a b l e promoted f r e s h
c a t a l y s t s , have been used. Their most important d a t a are compiled i n Table Prior treatment containing
to
at
1.
measurements t h e c a t a l y s t samples have been s t a b i l i z e d by h e a t 500°C
2% by
for volume
2 hours i n air, followed by a pretreatment with air of
carbon
monoxide
at
5OO0C
for
30 minutes.
conversions have been determined at d i f f e r e n t temperatures. Values of carbon monoxide conversion were p l o t t e d a g a i n s t
Subsequently,
carbon monoxide
567
TABLE 1. Data of the catalysts used Catalysts Chemical composition, % by w t .
A1203
28.00 0.20 0.08
Na20 Fe Physical properties Apparent bulk density (g/rnl) Pore volume Surface area
AF
(ml/ g 1 (m2/g)
BF
46.80 0.25 0.76
0.53
0.84
0.50 390
0.27 122
CF
32.00 0.70
0.35
0.85 0.19 200
(Reprinted with pmmission from Studies in Surface Science and Catalysis, Vol.
34, p. 452. Elsevier Science Publishers, B.V.)
temperature and these curves have been used to characterize the carbon monoxide conversion activities of the catalyst samples. The measured carbon monoxide conversion values were corrected by substracting the value of carbon monoxide converted thermally, i.e. in the empty reactor. In order to determine the effect of thermal treatment on carbon monoxide conversion activity, catalyst samples were treated at 7OO0C for 3 hours in air prior to measurements. The influence of hydrothermal effects on carbon monoxide conversion activity was modeled by treatment of the catalyst samples in 100% steam at 75OoC for 6 hours before GO-conversion measurements. The effect of transition metals on carbon monoxide conversion activity was tested by impregnating fresh catalyst sample BF with aqueous solutions of nickel nitrate, ferric nitrate and m o n i u m vanadate, respectively to different concentration levels, drying at 120°C for 3 hours and calcining at 7OO0C for 3 hours before conversion measurements, For the determination of coke combustion kinetics, fresh catalyst BF was mixed with different amounts of a comercially available coke combustion improver concentrate. Laboratory catalytic cracking runs have been carried out with these catalysts at 490-495°C ith a standard FCC feed (vacuum gas oil) in the presence of argon carrier gas. The coked catalyst samples were regenerated in a computer coupled Mettler TA-3000 System type thermobalance in air, with linear temperature rate of 15OC/min over a temperature range of 25 to 700%.
568
RESULTS AND DISCUSSION Effect of thermal and hydrothermal treatment Figure 1. shows the carbon monoxide conversion vs. temperature curves for the catalysts investigated. The samples tested were the following: - fresh catalysts AF, BF, and CF, - equilibrium catalysts AE and BE, obtained from industrial fluid catalytic cracking units using fresh catalyst AF and BF, respectively, - thermally treated fresh catalysts AT, BT and CT, - hydrothermally treated fresh catalysts AH, BH, and CH, where subscripts F, E, T and H refer to fresh, equilibrium, thermally and hydrothermally treated catalysts, respectively. Figure 1. shows that different promoted catalysts behave differently on hydrothermal and thermal treatment. With catalyst A the equilibrium form AE is much more active than the fresh catalyst AF whereas the equilibrated catalyst
BE is less active than fresh catalyst BF. The CO-conversion activity of fresh catalyst BF is improved by thermal treatment and even more by hydrothermal treatment. The CO-conversion activity of fresh catalyst AF is increased by thermal treatment, even more by hydrothermal treatment whereas equilibrium catalyst AE shows the highest activity. Catalyst C shows opposite trends as both thermal and hydrothermal treatment decreases its CO-converting activity considerably. Data in Figure 1 prove that upon hydrothermal treatment CO-conversion activities of promoted catalysts from different manufacturers may either increase of decrease. This finding explains why literature data on the effect of hydrothermal treatment are contradictory (See References 1, 10, 11, 12, 13) Effect of transition metals Equilibrium cracking catalysts contain different amounts of transition metals (nickel, iron and vanadium) deposited on the catalyst surface from feeds, containing metals in the form of organic complexes. Usual levels of these metals on equilibrium catalysts vary from a few hundred up to several thousand ppm, depending on the feedstock processed (refs. 7, 14, 15). Transition metals, being dehydrogenation catalysts impair product composition by enhancing coke make and hydrogen yield, decreasing conversion and gasoline yield (ref. 7). Some authors report that transition metals m y improve regenerability of cracking catalysts (ref.161, but there is hardly any information as to the quantitative effect of these metals on the regeneration behaviour of promoted cracking catalysts.
569
0
200
-.
10.,o oa. C
Fig. 1.
4 00
500
600
Effect of thermal and hydrothermal treatment on comercial promoted cracking catalysts (Reprinted with permission from Studies in Surfme Science and Catalysis, Vol. %., p. 454, Elsevier Science Publishers
B.V.)
570
L
I
1000 Fig.
2.
Effect
of
different
of c a t a l y s t BF.
3000 transition
so00
*
PPm Ni
metals on t h e CO-oxidation a c t i v i t y
571 Our carbon
experimental
monoxide
transition
metal
content
question.
In
empirical
evaluation
order
BF prove t h a t its
d a t a obtained with promoted c a t a l y s t
conversion
activity
generally
decreases
a way s p e c i f i c t o
in
the
with
increasing
t r a n s i t i o n metal i n
compare t h e e f f e c t s of t r a n s i t i o n metal poisoning an
to
method
has
been
used: carbon monoxide conversion v s .
curves were i n t e g r a t e d over t h e temperature range of 240 t o 5OO0C
temperature
t h e a r e a under t h e curve measured with unpromoted c a t a l y s t was assigned a
and
promoter
activity
100%. Carbon poisoned
catalyst
0% whereas f o r t h e promoted c a t a l y s t a value of
of
conversion
curves obtained with t h e t r a n s i t i o n metal
samples were i n t e g r a t e d over t h e same temperature i n t e r v a l
a c t i v i t y was read from a c a l i b r a t i o n diagram. Promoter a c t i v i t y
promoter
and
value
monoxide
values were p l o t t e d i n function of t r a n s i t i o n metal content (see Fig. 2.). Figure with
the
2/a
shows
first
t h a t f o r vanadium t h e promoter a c t i v i t y s h a r p l y drops
few hundred
ppm of metal loading, f l a t t e n i n g out at higher
loadings, up t o 5000 ppm. 2/b shows t h a t with i r o n t h e a c t i v i t y d e c l i n e s less s t e e p l y up t o
Figure
concentrations of cca 4000 ppm; at higher i r o n concentrations
metal
a slight
i n c r e a s e i n a c t i v i t y can be noticed.
As
on
shown
conversion
Figure
2/c,
nickel
behaves d i f f e r e n t l y : carbon monoxide
sharply decreases up t o a metal content of 200 ppm, then
activity
i n c r e a s e s s l i g h t l y up t o 500-1000 ppm n i c k e l content t o a f l a t maximum. Carbon
monoxide
conversion
activities
of
transition
metal
poisoned
c a t a l y s t samples have a l s o been measured a f t e r hydrothermal t r e a t m e n t . Results are
shown
Figure 2 with broken l i n e s . The r e s u l t s show t h a t hydrothermal
on
treatment f u r t h e r decreases t h e a c t i v i t y of t r a n s i t i o n metal loaded c a t a l y s t s , catalysts
loaded
with
6000 ppm metals
cca
lose
their
carbon
monoxide
conversion a c t i v i t y almost completely. The
gradual
concentration simply
decrease
in
cover
the
the
of
case
CO-conversion
of
a c t i v i t y with i n c r e a s i n g metal
i r o n and vanadium suggests t h a t t h e s e metals
catalytically
active
sites,
whereas
with
nickel
the
pronounced v a l l e y on t h e a c t i v i t y v s . n i c k e l concentration curves suggests t h e p o s s i b l e formation of a s u r f a c e a l l o y with d i f f e r e n t c a t a l y t i c p r o p e r t i e s . The slight
increase
of CO-converting a c t i v i t y found at high i r o n loadings m y be
a t t r i b u t e d t o t h e c a t a l y t i c p r o p e r t i e s of i r o n reported f o r t h i s concentration range i n t h e l i t e r a t u r e ( r e f . 17). E f f e c t of sulphur compounds Feedstocks
of
catalytic
cracking
usually c o n t a i n s e v e r a l thousand ppm
(0.3-1.0% by weight) of sulphur i n form of organic compounds. I n t h e cracking
572
r e a c t o r , t h e se compounds are p a r t i a l l y converted t o coke, and i n t h e oxidiz ing atmosphere of the regenerator t o sulphur oxides.
In order t o test t h e e f f e c t of sulphur compounds on t h e a c t i v i t y of t h e promoted cracking c a t a l y s t BF had been exposed t o 5000 ppm H2S i n
promoter,
hydrogen gas stream az 49OoC f o r 1 hour and t he n its CO-oxidation a c t i v i t y has been
measured.
activity
The
compared
catalyst to
the
did
not
show any change i n t h e CO-conversion
unsulphided
c a t a l y s t , i . e . sulphida tion does not
e f f e c t t h e a c t i v i t y of t h e promoter. The catalyst
effect
BF h a s
S02-concentrations
of
sulphur
dioxide
on CO-oxidation
a c t i v i t y of promoted
been measured by determining t h e CO-conversion at d i f f e r e n t in
the
CO/air
Sulphur dioxide causes a s l i g h t
stream.
decrease in
Re sults
are
shown i n Figure 3 .
CO-conversion. The shape of t h e
curve i n t h e SO*-concentration i n t e r v a l 0,03-3% by volume i s loga rithm ic . Over
3%by v o l . S02-content t h e CO-conversion does not decrease any more. The
decrease
a f t e r having
in
stopped
t h e CO-oxidation a c t i v i t y caused by SO2 is r e v e r s i b l e : the
SOP-flow,
CO-conversion was re -e sta blishe d, i . e .
promoter/sulphur compounds formed on the s u r fa c e are not s t a b l e and e x i s t only i n t h e presence of S02. This who proved
conclusion that
in
i s confirmed by observations of Wang e t al. ( r e f . 18.) the
presence
of
air at higher temperatures surfa c e
sulphur/noble m e t a l compounds decompose mainly t o t h e metal and metal oxide.
Fig. 3. E f f e c t of sulphur dioxide on CO-conversion a c t i v i t y of promoted f r e s h cracking c a t a l y s t BF.
573
Kinetics of coke combustion Comnercial cracking catalyst BF was mixed with different amounts of a comrcially available oxidation improving concentrate. The samples contained 0, 0,05, 0,1, 0,5 and 2,0% by weight of the concentrate. Cracking experiments were run with these samples after calcination at 700°C for 2 hours in air. The coked catalyst samples were cooled down in an inert atmosphere. Computer aided differential thermal gravimetry curves obtained in air with respect to promoter concentration with the Mettler thermobalance were used to calculate kinetic constants (reaction order, activition energy, preexponential factor) assuming the validity of the Arrhenius model (refs. 19, 20). Data obtained are shown in Table 2. As shown in Table 2., the reaction order of coke combustion in air is practically 1 , and kinetic factors do not depend on coke level of the catalyst, however values of activation energy and pre-exponential factor change with promoter concentration. The latter correlations are presented in Figure 4. Figure 5. is a plot of kinetic constants of coke oxidation vs. the onethird power of oxidation improver concentration, showing a linear correlation. This finding explains the theoretical basis of empirical correlations developed earlier (refs. 1, 10) stating that regenerability is a linear function of the one-third power of oxidation improver concentration. TABLE 2. Effect of concetration of oxidation improver on the kinetic constants of coke combustion. Promoter Coke on concentration the w t % catalyst
Reaction order
Activation energy kJ/mol
he-exponential factor In KO
wt%
0
6.08
1 .og
72.7
5.28
0.05
4.62
1.05
71.8
4.95
0.10
5.32
1 .oo
66.5
4.12
0.50
5.33
0.96
62.3
3.39
2.00
4.98
1.04
55.9
2.61
574
0
Fig. 4. Relationship between kinetic constants of coke oxidation and oxidation improver concentration.
Fig. 5. Kinetic constants vs. oxidation impover concentration.
575
ACKNOWLEEEMENT The authors wish to express their thanks to Mr. G. Pokol, Associate Professor and to the Analytical Department of Gedeon Richter Pharmaceutical Works Ltd. (Budapest) f o r their kind help in carrying out and interpreting thermal analyses.
REFERENCES 1 A.W. Chester, A.B. Schwartz and W.A. Stover, CHEMTECH, 1 (1981) 50-58 2 J.R. Murphy and M. Soudek, Oil Gas J. 75 ( 3 ) (1977) 70-76 3 USP 4.064.039 4 F.D. Hartzell and A.W. Chester, Hydrocarbon Processing, 58 (7) (1979)
137-140 5 L. Rheaume, R.E. Ritter, J.J. Blazek and J.A. Montgomery, Oil Gas J., 74 (20) (1976) 103-110 6 L. Rheaume, R.E. Ritter, J.J. Blazek and J.A. Montgomery, Oil Gas J., 74 (21) (1976) 66-70 7 E.T. Habib, Jr., H. Owen, P.W. Snyder, C.W. Streed and P.B. Venuto, Ind. Eng. Chem. Prod. Res. Dev., 16 (1977) 291-296 8 A.W. Chester and W.A. Stover, Ind. Eng. Chem. Prod. Res. Dev., 16 (1977) 285-289 9 AKZO Ketjen Technical Information FCC 79/53 10 P. Steingaszner, A . Sziics, I?. L. hd& and T. Mhdy, Acta Phys. Chem. 31. (1985) 397-403 11 USP 4.097.410 12 USP 4.151.121 13 USP 4.164.465 14 R.R. Edison, J.O. Siemssen and G.P. Masologites, Hydrocarbon Processing, 55 (5) 133-138 15 G.H. Dale and D.L. McKay, Hydrocarbon Processing, 56 (9) (1977) 97-102 16 W.F. Pansing, A.1.Ch.E. Journal, 2 (1956) 71-76 17 DBP 25 07 343 18 T.Wang, A. Vazquez, A. Kato and L.D. Schmidt, J. Catal. 78 (1982) 306-318 19 Gy. Pokol and S. GAl, Magy. KCm. Foly. 91 (9) (1985) 404-411 20 Gy. Pokol and S. GAl, Magy. KCm. Foly. 91 (9) (1985) 411-422
565
REGENERATION BEHAVIOUR OF PLATINUM GROUP METALS PROMOTED CRACKING CATALYSTS P. STEINGASZNER, A.
szucs & L. MERI
Department of Chemical Technology, Technical University of Budapest, H-1521 Budapest, Budafoki 6 t 8. (Hungary)
ABSTRACT Regeneration behaviour of platinum group metals promoted cracking c a t a l y s t s has been i n v es t i g at ed by means of carbon monoxide oxidation a c t i v i t y tests and high s e n s i t i v i t y thermoanalytical methods. E f f e c t s of physical and chemical f a c t o r s - such as thermal and hydrothermal tre a tm e nt, t r a n s i t i o n metals c o n t e n t , presence of sulphur compounds as hydrogen sulphide and sulphur dioxide - on t h e carbon monoxide oxidation a c t i v i t y of s e v e r a l c o m r c i a l cracking c a t a l y s t s have been determined. Computer aided d i f f e r e n t i a l thermogravimetry has been used t o d es cr i be t h e dynamics of coke oxidation on promoted cracking c a t a l y s t s and t o determine k i n e t i c c o r r e l a t i o n s i n func tion of promoter concentration.
INTRODUCTION Catalytic
cracking
petroleum r e f i n i n g oils
into
feed
is
particles, catalyst
is
one
industry
of
for
the
most
important
processes
i n the
t h e conversion of heavy f r a c t i o n s of crude
valuable l i g h t e r products. During t h e cracking cycle a part of t h e converted
to
rendering can
he
coke which
deposits
on the surfa c e of t h e c a t a l y s t
them less a c t i v e f o r cracking. Cracking a c t i v i t y of t h e
r es t o r ed
by removal of t h e coke by burning with c ontrolle d
of air. The cracking a c t i v i t y of t h e regenerated c a t a l y s t strongly on t h e coke remaining a f t e r r eg ene ra tion, t h e r e f o r e , e s p e c i a l l y with r e g u l a r channel s t r u c t u r e z e o l i t i c cracking c a t a l y s t a coke l e v e l of less than 0.1% is m d a t o r y i n order t o g e t best r e s u l t s . Proper coke removal can be e f f e c t e d by c ar r y i n g out t h e regeneration at high temperature ( r e f . l > , i n two s t e p s ( r e f . 2) and/or by using coke oxidation improvers e i t h e r incorporated i n t o t h e cracking c a t a l y s t , or using them i n a concentrated form, added t o the c a t a l y s t ( r e f s . 1 , 7-61. Members of t h e platinum group of t h e Pe riodic Table of Elements a r e e x c e l l e n t oxidation c a t a l y s t s , and, according t o t h e pa te nt l i t e r a t u r e , t h e i r presence - alone or i n combination - on t h e cracking c a t a l y s t s i n ppm amounts results i n near complete combustion of t h e coke, preventing damaging addition
depends
566
afterburns
in
regenerator
vessel,
giving
lower coke on t h e regenerated c a t a l y s t and
coke
cracking from
make,
however
monoxide
ability
b e t t e r h e a t economy and - due t o
higher g a s o l i n e y i e l d s with lower gas
composition d a t a on c o m e r c i a l l y a v a i l a b l e promoted
are not a v a i l a b l e . The advantages mentioned r e s u l t m i n l y
catalysts
the
-
of
group metals t o c a t a l y z e oxidation of carbon
platinum
formed during r e g e n e r a t i o n t o carbon dioxide i n t h e dense
primarily
c a t a l y s t phase. I n d u s t r i a l experience has shown t h e coke combustion a c t i v i t y of oxidation improvers
to
oxidation
promoters
hydrotermal
decline
during used
repeated
with
them
use. are
As
cracking c a t a l y s t s and t h e
s u b j e c t e d t o repeated thermal and
c y c l e s , oxidative and reducing atmospheres i n t h e r e g e n e r a t o r and
r e a c t o r r e s p e c t i v e l y , and a d d i t i o n a l l y metals from t h e feed - n i c k e l , vanadium and i r o n - accumulate on them, f u r t h e r , d i f f e r e n t sulphur compounds, mainly as and hydrogen sulphide i n t h e cracking r e a c t o r and as sulphur oxides i n
thiols the
regenerator
investigations
influence
combustion a c t i v i t y ( r e f s . 1, 7, 8 ) ,
coke
were s t a r t e d t o show t h e q u a n t i t a t i v e e f f e c t s of t h e s e f a c t o r s
on carbon monoxide sensitivity
their
oxidation
activity.
Additionally,
computer aided high
methods have been used t o shed l i g h t on k i n e t i c
thermoanalytical
a s p e c t s of t h e regeneration process. EXPERIMENTAL The
regeneration
effectiveness
carbon monoxide/carbon experiments carbon been in
dioxide
1.) o r
(ref.
monoxide
specified
behaviour
of
promoted
cracking
catalyts
and
the
of oxidation improvers may be s t u d i e d e i t h e r by determining t h e by
ratio
i n f l u e gases from batch r e g e n e r a t i o n
measuring t h e carbon monoxide conversion i n a
and
oxygen
c o n t a i n i n g gas
led
over
the
c a t a l y s t under
conditions
(refs.
5,9). I n t h e p r e s e n t work t h e latter method has
used by feeding a gas stream containing 2 % by volume of carbon monoxide
air i n t o an e l e c t r i c a l l y heated isothermal q u a r t z r e a c t o r containing t h e
c a t a l y s t , at a flow rate of 30 l i t e r s / h o u r . The carbon monoxide content of t h e feed
gas,
infrared
as t h a t
as well analyzers.
The
of
volume
t h e e f f l u e n t has been measured by means of of
the
catalysts
was
6.2
ml
in
all
experiments. Catalyst
AF,
BF,
and
CF, all c o m e r c i a l l y a v a i l a b l e promoted f r e s h
c a t a l y s t s , have been used. Their most important d a t a are compiled i n Table Prior treatment containing
to
at
1.
measurements t h e c a t a l y s t samples have been s t a b i l i z e d by h e a t 500°C
2% by
for volume
2 hours i n air, followed by a pretreatment with air of
carbon
monoxide
at
5OO0C
for
30 minutes.
conversions have been determined at d i f f e r e n t temperatures. Values of carbon monoxide conversion were p l o t t e d a g a i n s t
Subsequently,
carbon monoxide
567
TABLE 1. Data of the catalysts used Catalysts Chemical composition, % by w t .
A1203
28.00 0.20 0.08
Na20 Fe Physical properties Apparent bulk density (g/rnl) Pore volume Surface area
AF
(ml/ g 1 (m2/g)
BF
46.80 0.25 0.76
0.53
0.84
0.50 390
0.27 122
CF
32.00 0.70
0.35
0.85 0.19 200
(Reprinted with pmmission from Studies in Surface Science and Catalysis, Vol.
34, p. 452. Elsevier Science Publishers, B.V.)
temperature and these curves have been used to characterize the carbon monoxide conversion activities of the catalyst samples. The measured carbon monoxide conversion values were corrected by substracting the value of carbon monoxide converted thermally, i.e. in the empty reactor. In order to determine the effect of thermal treatment on carbon monoxide conversion activity, catalyst samples were treated at 7OO0C for 3 hours in air prior to measurements. The influence of hydrothermal effects on carbon monoxide conversion activity was modeled by treatment of the catalyst samples in 100% steam at 75OoC for 6 hours before GO-conversion measurements. The effect of transition metals on carbon monoxide conversion activity was tested by impregnating fresh catalyst sample BF with aqueous solutions of nickel nitrate, ferric nitrate and m o n i u m vanadate, respectively to different concentration levels, drying at 120°C for 3 hours and calcining at 7OO0C for 3 hours before conversion measurements, For the determination of coke combustion kinetics, fresh catalyst BF was mixed with different amounts of a comercially available coke combustion improver concentrate. Laboratory catalytic cracking runs have been carried out with these catalysts at 490-495°C ith a standard FCC feed (vacuum gas oil) in the presence of argon carrier gas. The coked catalyst samples were regenerated in a computer coupled Mettler TA-3000 System type thermobalance in air, with linear temperature rate of 15OC/min over a temperature range of 25 to 700%.
568
RESULTS AND DISCUSSION Effect of thermal and hydrothermal treatment Figure 1. shows the carbon monoxide conversion vs. temperature curves for the catalysts investigated. The samples tested were the following: - fresh catalysts AF, BF, and CF, - equilibrium catalysts AE and BE, obtained from industrial fluid catalytic cracking units using fresh catalyst AF and BF, respectively, - thermally treated fresh catalysts AT, BT and CT, - hydrothermally treated fresh catalysts AH, BH, and CH, where subscripts F, E, T and H refer to fresh, equilibrium, thermally and hydrothermally treated catalysts, respectively. Figure 1. shows that different promoted catalysts behave differently on hydrothermal and thermal treatment. With catalyst A the equilibrium form AE is much more active than the fresh catalyst AF whereas the equilibrated catalyst
BE is less active than fresh catalyst BF. The CO-conversion activity of fresh catalyst BF is improved by thermal treatment and even more by hydrothermal treatment. The CO-conversion activity of fresh catalyst AF is increased by thermal treatment, even more by hydrothermal treatment whereas equilibrium catalyst AE shows the highest activity. Catalyst C shows opposite trends as both thermal and hydrothermal treatment decreases its CO-converting activity considerably. Data in Figure 1 prove that upon hydrothermal treatment CO-conversion activities of promoted catalysts from different manufacturers may either increase of decrease. This finding explains why literature data on the effect of hydrothermal treatment are contradictory (See References 1, 10, 11, 12, 13) Effect of transition metals Equilibrium cracking catalysts contain different amounts of transition metals (nickel, iron and vanadium) deposited on the catalyst surface from feeds, containing metals in the form of organic complexes. Usual levels of these metals on equilibrium catalysts vary from a few hundred up to several thousand ppm, depending on the feedstock processed (refs. 7, 14, 15). Transition metals, being dehydrogenation catalysts impair product composition by enhancing coke make and hydrogen yield, decreasing conversion and gasoline yield (ref. 7). Some authors report that transition metals m y improve regenerability of cracking catalysts (ref.161, but there is hardly any information as to the quantitative effect of these metals on the regeneration behaviour of promoted cracking catalysts.
569
0
200
-.
10.,o oa. C
Fig. 1.
4 00
500
600
Effect of thermal and hydrothermal treatment on comercial promoted cracking catalysts (Reprinted with permission from Studies in Surfme Science and Catalysis, Vol. %., p. 454, Elsevier Science Publishers
B.V.)
570
L
I
1000 Fig.
2.
Effect
of
different
of c a t a l y s t BF.
3000 transition
so00
*
PPm Ni
metals on t h e CO-oxidation a c t i v i t y
571 Our carbon
experimental
monoxide
transition
metal
content
question.
In
empirical
evaluation
order
BF prove t h a t its
d a t a obtained with promoted c a t a l y s t
conversion
activity
generally
decreases
a way s p e c i f i c t o
in
the
with
increasing
t r a n s i t i o n metal i n
compare t h e e f f e c t s of t r a n s i t i o n metal poisoning an
to
method
has
been
used: carbon monoxide conversion v s .
curves were i n t e g r a t e d over t h e temperature range of 240 t o 5OO0C
temperature
t h e a r e a under t h e curve measured with unpromoted c a t a l y s t was assigned a
and
promoter
activity
100%. Carbon poisoned
catalyst
0% whereas f o r t h e promoted c a t a l y s t a value of
of
conversion
curves obtained with t h e t r a n s i t i o n metal
samples were i n t e g r a t e d over t h e same temperature i n t e r v a l
a c t i v i t y was read from a c a l i b r a t i o n diagram. Promoter a c t i v i t y
promoter
and
value
monoxide
values were p l o t t e d i n function of t r a n s i t i o n metal content (see Fig. 2.). Figure with
the
2/a
shows
first
t h a t f o r vanadium t h e promoter a c t i v i t y s h a r p l y drops
few hundred
ppm of metal loading, f l a t t e n i n g out at higher
loadings, up t o 5000 ppm. 2/b shows t h a t with i r o n t h e a c t i v i t y d e c l i n e s less s t e e p l y up t o
Figure
concentrations of cca 4000 ppm; at higher i r o n concentrations
metal
a slight
i n c r e a s e i n a c t i v i t y can be noticed.
As
on
shown
conversion
Figure
2/c,
nickel
behaves d i f f e r e n t l y : carbon monoxide
sharply decreases up t o a metal content of 200 ppm, then
activity
i n c r e a s e s s l i g h t l y up t o 500-1000 ppm n i c k e l content t o a f l a t maximum. Carbon
monoxide
conversion
activities
of
transition
metal
poisoned
c a t a l y s t samples have a l s o been measured a f t e r hydrothermal t r e a t m e n t . Results are
shown
Figure 2 with broken l i n e s . The r e s u l t s show t h a t hydrothermal
on
treatment f u r t h e r decreases t h e a c t i v i t y of t r a n s i t i o n metal loaded c a t a l y s t s , catalysts
loaded
with
6000 ppm metals
cca
lose
their
carbon
monoxide
conversion a c t i v i t y almost completely. The
gradual
concentration simply
decrease
in
cover
the
the
of
case
CO-conversion
of
a c t i v i t y with i n c r e a s i n g metal
i r o n and vanadium suggests t h a t t h e s e metals
catalytically
active
sites,
whereas
with
nickel
the
pronounced v a l l e y on t h e a c t i v i t y v s . n i c k e l concentration curves suggests t h e p o s s i b l e formation of a s u r f a c e a l l o y with d i f f e r e n t c a t a l y t i c p r o p e r t i e s . The slight
increase
of CO-converting a c t i v i t y found at high i r o n loadings m y be
a t t r i b u t e d t o t h e c a t a l y t i c p r o p e r t i e s of i r o n reported f o r t h i s concentration range i n t h e l i t e r a t u r e ( r e f . 17). E f f e c t of sulphur compounds Feedstocks
of
catalytic
cracking
usually c o n t a i n s e v e r a l thousand ppm
(0.3-1.0% by weight) of sulphur i n form of organic compounds. I n t h e cracking
572
r e a c t o r , t h e se compounds are p a r t i a l l y converted t o coke, and i n t h e oxidiz ing atmosphere of the regenerator t o sulphur oxides.
In order t o test t h e e f f e c t of sulphur compounds on t h e a c t i v i t y of t h e promoted cracking c a t a l y s t BF had been exposed t o 5000 ppm H2S i n
promoter,
hydrogen gas stream az 49OoC f o r 1 hour and t he n its CO-oxidation a c t i v i t y has been
measured.
activity
The
compared
catalyst to
the
did
not
show any change i n t h e CO-conversion
unsulphided
c a t a l y s t , i . e . sulphida tion does not
e f f e c t t h e a c t i v i t y of t h e promoter. The catalyst
effect
BF h a s
S02-concentrations
of
sulphur
dioxide
on CO-oxidation
a c t i v i t y of promoted
been measured by determining t h e CO-conversion at d i f f e r e n t in
the
CO/air
Sulphur dioxide causes a s l i g h t
stream.
decrease in
Re sults
are
shown i n Figure 3 .
CO-conversion. The shape of t h e
curve i n t h e SO*-concentration i n t e r v a l 0,03-3% by volume i s loga rithm ic . Over
3%by v o l . S02-content t h e CO-conversion does not decrease any more. The
decrease
a f t e r having
in
stopped
t h e CO-oxidation a c t i v i t y caused by SO2 is r e v e r s i b l e : the
SOP-flow,
CO-conversion was re -e sta blishe d, i . e .
promoter/sulphur compounds formed on the s u r fa c e are not s t a b l e and e x i s t only i n t h e presence of S02. This who proved
conclusion that
in
i s confirmed by observations of Wang e t al. ( r e f . 18.) the
presence
of
air at higher temperatures surfa c e
sulphur/noble m e t a l compounds decompose mainly t o t h e metal and metal oxide.
Fig. 3. E f f e c t of sulphur dioxide on CO-conversion a c t i v i t y of promoted f r e s h cracking c a t a l y s t BF.
573
Kinetics of coke combustion Comnercial cracking catalyst BF was mixed with different amounts of a comrcially available oxidation improving concentrate. The samples contained 0, 0,05, 0,1, 0,5 and 2,0% by weight of the concentrate. Cracking experiments were run with these samples after calcination at 700°C for 2 hours in air. The coked catalyst samples were cooled down in an inert atmosphere. Computer aided differential thermal gravimetry curves obtained in air with respect to promoter concentration with the Mettler thermobalance were used to calculate kinetic constants (reaction order, activition energy, preexponential factor) assuming the validity of the Arrhenius model (refs. 19, 20). Data obtained are shown in Table 2. As shown in Table 2., the reaction order of coke combustion in air is practically 1 , and kinetic factors do not depend on coke level of the catalyst, however values of activation energy and pre-exponential factor change with promoter concentration. The latter correlations are presented in Figure 4. Figure 5. is a plot of kinetic constants of coke oxidation vs. the onethird power of oxidation improver concentration, showing a linear correlation. This finding explains the theoretical basis of empirical correlations developed earlier (refs. 1, 10) stating that regenerability is a linear function of the one-third power of oxidation improver concentration. TABLE 2. Effect of concetration of oxidation improver on the kinetic constants of coke combustion. Promoter Coke on concentration the w t % catalyst
Reaction order
Activation energy kJ/mol
he-exponential factor In KO
wt%
0
6.08
1 .og
72.7
5.28
0.05
4.62
1.05
71.8
4.95
0.10
5.32
1 .oo
66.5
4.12
0.50
5.33
0.96
62.3
3.39
2.00
4.98
1.04
55.9
2.61
574
0
Fig. 4. Relationship between kinetic constants of coke oxidation and oxidation improver concentration.
Fig. 5. Kinetic constants vs. oxidation impover concentration.
575
ACKNOWLEEEMENT The authors wish to express their thanks to Mr. G. Pokol, Associate Professor and to the Analytical Department of Gedeon Richter Pharmaceutical Works Ltd. (Budapest) f o r their kind help in carrying out and interpreting thermal analyses.
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